Efficient carrier injection in a semiconductor device

ABSTRACT

Semiconductor devices such as VCSELs, SELs, LEDs, and HBTs are manufactured to have a wide bandgap material near a narrow bandgap material. Electron injection is improved by an intermediate structure positioned between the wide bandgap material and the narrow bandgap material. The intermediate structure is an inflection, such as a plateau, in the ramping of the composition between the wide bandgap material and the narrow bandgap material. The intermediate structure is highly doped and has a composition with a desired low electron affinity. The injection structure can be used on the p-side of a device with a p-doped intermediate structure at high hole affinity.

CROSS-REFERENCE TO RELATED APPLICATIONS

This application is a divisional of U.S. Utility application Ser. No. 11/735,993, titled EFFICIENT CARRIER INJECTION IN A SEMICONDUCTOR DEVICE, filed Apr. 16, 2007, which is a continuation in part of U.S. Utility application Ser. No. 11/461,353, titled LIGHT EMITTING SEMICONDUCTOR DEVICE HAVING AN ELECTRICAL CONFINEMENT BARRIER NEAR THE ACTIVE REGION, filed Jul. 31, 2006, which is a continuation in part of U.S. Utility application Ser. No. 11/091,656, titled DISTRIBUTED BRAGG REFLECTOR FOR OPTOELECTRONIC DEVICE, filed Mar. 28, 2005, which claims priority to U.S. Provisional Application No. 60/605,737, titled DISTRIBUTED BRAGG REFLECTOR FOR OPTOELECTRONIC DEVICE, filed Aug. 31, 2004, 2004, each of which are incorporated herein by reference in their entireties.

BACKGROUND OF THE INVENTION

1. Field of the Invention

The invention generally relates to semiconductor devices such as semiconductor lasers, light emitting diodes, and heterojunction bipolar transistors. More specifically, the invention relates to efficient injection of electrons or holes from a wider bandgap semiconductor material to a narrower bandgap semiconductor material.

2. Related Technology

Vertical cavity surface emitting lasers (VCSELs), surface emitting lasers (SELs), light Emitting Diodes (LEDs), and heterojunction bipolar transistors (HBTs) are becoming increasingly important for a wide variety of applications including optical interconnection of integrated circuits, optical computing systems, optical recording and readout systems, and telecommunications.

VCSELs, SELs, and LEDs are generally formed as a semiconductor diode. A diode is formed from a junction between a p-type material and an n-type material. In VCSELs, the p-type semiconductor material is most often aluminum gallium arsenide (AlGaAs) doped with a material such as carbon that introduces free holes or positive charge carriers, while the n-type semiconductor material is typically AlGaAs doped with a material, such as silicon, that introduces free electrons, or negative charge carriers.

The PN junction forms an active region. The active region typically includes a number of quantum wells. Free carriers in the form of holes and electrons are injected into the quantum wells when the PN junction is forward biased by an electrical current. At a sufficiently high bias current, the injected minority carriers form a population inversion in the quantum wells that produces optical gain, which is used inside a resonant cavity to cause lasing. The resonant cavity is formed by properly spacing mirrors on either side of the active region.

Free carriers that escape the quantum wells into the surrounding semiconductor material and recombine there do not contribute to the optical gain. These events are parasitic currents that generate heat and reduce the efficiency of the light emitting device. This “carrier leakage” is one of the causes of the rollover of the light vs. current curve. Current can only be increased so much and then light output reaches a maximum and drops off. Generally, higher temperatures result in lower maximum light output partially because the thermal energy of the carriers, electrons, and holes is increased allowing a larger fraction to contribute to carrier leakage. Electrical confinement in the active region can be particularly problematic in VCSEL devices, which tend to require high current densities for operation and is made worse in the highest frequency VCSELs where the highest current densities are used.

To improve current confinement, most semiconductor lasers have confining layers next to the active region. The confining layers have a bandgap that is substantially wider than the bandgap of the quantum wells and quantum well barriers. For carriers to escape from the active region, the carriers need higher energy to pass through the confining layer. The higher energy requirements in the confining layer make it more likely that carriers will remain in the active region and contribute to stimulated emission at the desired wavelength.

One potential concern with confining electrons in the active region is the effect that the confining layer has on the injection of carriers into the active region. In some cases, measures taken to confine carriers in the active region can also decrease the efficiency of injecting the carriers into the active region.

BRIEF SUMMARY OF THE INVENTION

The present invention relates to improving the electron or hole injection efficiency of semiconductor devices such as VCSELs, SELs, LEDs, and HBTs that have a wide bandgap material adjacent or near a narrow bandgap material. (e.g., a high aluminum confining region near a low aluminum active region in an AlGaAs or AlInGaAs system). The wide bandgap material is separated from the narrow bandgap material by a transition region that provides ramping of the composition between the two regions. The carrier injection efficiency is improved by creating a point of inflection, (e.g., a plateau) in the composition ramping in the transition region. The inflection in the composition ramping is both doped and positioned at a composition with a desired low level of electron affinity (or high level of hole affinity for hole injection, where hole affinity is defined as the sum of the electron affinity and the bandgap energy). The combination of doping and low electron affinity at or near the composition inflection improves the electron injection. The improvement in electron or hole injection occurs because the portion of the transition region that ramps from the inflection to the narrow bandgap material (e.g., the quantum wells) is effectively modulation doped by the dopant in the material with low electron affinity (or high hole affinity).

The semiconductor devices of the present invention can be manufactured from any type of semiconductor suitable for forming junctions of wide bandgap and narrow bandgap material. Examples of suitable materials include III-V semiconductor materials (e.g., GaAs and/or InP based materials) and type IV materials such as SiGe.

In one embodiment, the semiconductor device can include an active region having one or more quantum wells and one or more quantum well barriers. Electrical confining layers sandwich the active region and provide optical gain efficiency by confining carriers to the active region. The confining layers have a region of high energy band gap which in the case of many III-V compounds translates to a high aluminum content (e.g., 70%-100% Al for the type III material). The aluminum content is selected to give the material a relatively wide bandgap, as compared to the bandgap in the quantum well barriers of the active region. The wide bandgap material gives the confining layer good carrier confinement and increases the efficiency in the active region. In an exemplary embodiment, the high aluminum region also includes an increase in doping. The confining layer can be doped with a p-type or n-type dopant depending on whether the confinement barrier is on the n-side or p-side of the active region.

A transition region for improving injection of electrons into the active region is positioned between the high aluminum content region and the outer quantum well barrier of the active region. In one embodiment, the transition region is manufactured from a III-V semiconductor material that includes aluminum, although other semiconductor materials can be used. The aluminum content in the transition region is ramped from the aluminum content in the quantum well barrier to the aluminum content in the high aluminum content confining region. If a non-aluminum material is used, the ramping is a ramping of the semiconductor component or components that widen the bandgap. For example, in a GaAsP system, the P content can be ramped (with a decrease in As); in a SiGe system the Si content can be ramped.

To improve the injection of electrons from the confining region (i.e., a high bandgap semiconductor material) to the quantum well barriers (i.e., a lower bandgap material), the transition region includes a doped intermediate structure in the transition between the active region and the confining region. The intermediate structure is doped, for example, with a donor doping of about 1e18/cm³. The doped intermediate structure is configured to have low electron affinity for n-type doping or high hole affinity for p-type doping.

In one embodiment, the intermediate structure can be described as an inflection in the ramping of the semiconductor composition (e.g., aluminum content). An inflection in the ramping occurs where the rate of ramping of the composition (from the active region toward the confining region) is increasing, then increases to a lesser degree, and then increases again (the ramping could similarly be described as a decrease in composition from the confining region toward the active region). A plateau in composition content can be created by decreasing the rate of ramping to zero over a particular depth of growth and then once again increasing the rate of ramping. A non-planar structure can be created by decreasing the rate of ramping to something greater than zero for a particular depth of growth. In one embodiment, the non-planar intermediate structures of can be linear or curved or a combination of these. In one embodiment, the intermediate structure is a flattening in the composition ramping for a depth of at least 5 nm, more preferably at least about 20 nm.

The composition at which the inflection is formed is selected to provide a low electron affinity structure. Electron affinity is a property of the semiconductor material. In some III-V semiconductor materials that include aluminum, electron affinity generally decreases with increasing aluminum until a minimum is reached and then electron affinity increases with increasing aluminum.

Forming the doped intermediate structure (i.e., the plateau or point of inflection) at or near the electron affinity minimum (or hole affinity maximum) improves the carrier injection efficiency of the device. The composition that gives a minimum or nearly a minimum depends on the particular semiconductor material being used. In one embodiment the intermediate structure comprises AlGaAs and the intermediate structure has an aluminum content of between about 0.4 to about 0.7. Alternatively, the intermediate structure comprises AlInGaP and the intermediate structure has an aluminum content between about 0.5 and 0.8. In another embodiment, the intermediate structure comprises GaAsP and the P content is between 0.4 and 0.6 (of the type V material). In yet another embodiment, the intermediate structure comprises SiGe and the Si content is between about 0.2 and 0.5.

The doping in the intermediate structure coupled with the low electron affinity (or high hole affinity) allows the intermediate structure to be a good carrier source to modulation dope the lower bandgap regions effectively (e.g., the active region and the ramp to the active region). The low electron affinity electron source in the intermediate structure provides low resistance electron conduction through the transition region. Facilitating carrier injection allows wider bandgap materials to be used in the confining layer without significantly reducing carrier injection into the active region. The improved confinement and/or improved carrier injection leads to a higher percentage of carriers recombining in the quantum wells where they provide the desired optical emission or optical gain.

In addition to the intermediate structure, the transition region can optionally include a substantially undoped portion. The undoped portion is positioned between the doped intermediate structure and the active region. Additional details regarding an undoped portion adjacent an active region are described in U.S. Pat. No. 7,023,896, which is hereby incorporated herein by reference.

In one alternative embodiment, the high aluminum confining region can be made thin (e.g., between 5 and 100 nm thick), thereby forming a confinement barrier. With sufficiently high aluminum in the confinement barrier, the aluminum content in the adjacent layer (i.e., the spacer layer) can be lowered (e.g., to less than 40%) while maintaining or improving the confinement of free carriers in the active region. The thinness of the confinement barrier can minimize vertical resistance and improves the manufacturability of the epitaxial structure. High aluminum content material typically requires higher temperatures for crystal growth. The higher temperatures can be difficult to work with and can degrade other semiconductor layers or cause imperfections in the crystal lattice. By making the confining layer thin, many of these problems are avoided or minimized.

These and other advantages and features of the present invention will become more fully apparent from the following description and appended claims, or may be learned by the practice of the invention as set forth hereinafter.

BRIEF DESCRIPTION OF THE DRAWINGS

To further clarify the above and other advantages and features of the present invention, a more particular description of the invention will be rendered by reference to specific embodiments thereof which are illustrated in the appended drawings. It is appreciated that these drawings depict only typical embodiments of the invention and are therefore not to be considered limiting of its scope. The invention will be described and explained with additional specificity and detail through the use of the accompanying drawings, in which:

FIG. 1 is an illustration of an exemplary vertical cavity surface emitting laser according to the present invention;

FIG. 2 illustrates the confining layers and active region of the laser of FIG. 1 in more detail;

FIG. 3 is a diagram of the aluminum profile of a semiconductor device according to the present invention; and

FIG. 4 is a graph showing the electron affinity for an AlGaAs material;

FIG. 5 is a graph showing electron conduction effective mass vs. aluminum content in AlGaAs; and

FIG. 6 is a diagram of the aluminum profile of another example semiconductor device according to the present invention.

DETAILED DESCRIPTION OF EXEMPLARY EMBODIMENTS

The present invention relates to semiconductor devices such as VCSELs, SELs, LEDs, and HTJs having an injection structure adjacent to the active region that improves the injection of electrons or holes from a wide bandgap semiconductor material into a narrower bandgap material of the active region.

For purposes of this invention, the term “substantially undoped” includes, but is not limited to, materials that have a minor amount of unintentional doping (e.g., unintentional doping that occurs by diffusion or other means).

For purposes of this invention, the term “hole affinity” is defined as the sum of the electron affinity and the energy bandgap.

For purposes of this invention, the content of Al in an AlGaAs or an AlGaInP system refers to the percent of Al in the AlGa fraction.

For purposes of this invention, the content of P in a GaAsP system refers the percent of P in the AsP fraction.

Various aspects of the present invention will now be illustrated in the context of a VCSEL. However, those skilled in the art will recognize that the features of the present invention can be incorporated into other light emitting semiconductor devices that have an active region, including but not limited to SELs and LEDs.

FIG. 1 shows a planar, current-guided, vertical cavity surface emitting laser (VCSEL) 100 having periodic layer pairs for top and bottom Bragg mirrors. A substrate 114 is formed on a bottom contact 112 and is doped with a first type of impurities (i.e., p-type or n-type dopant). A bottom mirror stack 116 is formed on substrate 114 and a bottom confining layer 118 is formed on bottom stack 116. The bottom confining layer 118 and a top confining layer 120 sandwich an active region 122. An upper mirror stack 124 is formed on the top confining layer 120. A metal layer 126 forms a contact on a portion of stack 124.

An isolation region 128 restricts the area of the current flow 130 through the active region 122. Region 128 can be formed by an ion implantation and/or oxidation.

Stacks 116 and 124 can be distributed Bragg reflector (DBR) stacks, and include periodic layers (e.g., 132 and 134). Periodic layers 132 and 134 are typically AlGaAs and AlAs, respectively, but can be made from other III-V semiconductor materials. Stacks 116 and 124 can be doped or undoped and the doping can be n-type or p-type depending on the particular VCSEL, SEL, or LED design. Various portions of the present discussion may refer to several configurations of the device.

Metal contact layers 112 and 126 can be ohmic contacts that allow appropriate electrical biasing of VCSEL 100. When VCSEL 100 is forward biased with a voltage on contact 126 different than the one on contact 112, active region 122 emits light 136, which passes through stack 124. Those skilled in the art will recognize that other configurations of contacts can be used to generate a voltage across active region 122 and generate light 136.

FIG. 2 illustrates the active region 122 and confining layers 118 and 120. Active region 122 is formed from one or more quantum wells 138 that are separated by quantum well barriers 140. In one embodiment, confining layers 118 and 120 include high aluminum content regions 142 and 144, respectively. The high aluminum content regions provide good carrier confinement in active region 122.

Confining region 120 includes a transition region 146 that is positioned between active region 122 and high aluminum content region 144. As discussed below, the combination of high aluminum content region 144 and the transition region 146 provide an injection structure with good carrier confinement and good electron injection.

Depending on the design of the device and the thickness of high aluminum content regions 142 and 144, the confining regions 118 and 120 can optionally include spacer layers 148 and 150, respectively. The thickness of spacer layers 148 and 150 is dependent upon the kind of device being fabricated. In a vertical cavity resonant device such as a VCSEL, or VECSEL the spacer layers provide resonant spacing between mirrors and provide that the quantum wells of the active region are centered on a peak of the optical field. In LEDs, spacer layers 148 and 150 can simply connect the injection structure to the remainder of the device and/or provide another function of the device.

The confining layers 118 and 120 and active region 122 are formed from one or more types of semiconductor materials. Examples of suitable semiconductor materials include GaAs, AlAs, InP, AlGaAs, InGaAs, InAlAs, InGaP, AlGaAsP, AlGaInP, InGaAsP, InAlGaAs, SiGe, or the like.

The various layers and regions in the semiconductor devices of the invention are created, at least in part, by varying the composition of the semiconductor material. For example in one embodiment, the aluminum content of a III-V semiconductor material can be varied. In one embodiment, the semiconductor material is Al_(x)Ga_(1-x)As, where x is between 0.0 and 1.0 (i.e., aluminum is 0.0% to 100%). Al_(x)Ga_(1-x)As is useful for making 850 nm VCSELs, which require high current densities and high optical output. In an alternative embodiment, the semiconductor material is (Al_(x)Ga_(1-x))InP where x is between 0.0 and 1.0 (i.e., aluminum is 0.0% to 100% for the AlGa fraction). The ratio of In to AlGa is typically selected to provide lattice matching and/or to provide a desired bandgap. In one embodiment the fraction of In in the AlGaInP system is about 0.51 of the type III materials.

The electron injection structure can be illustrated by showing the aluminum composition for the various layers and regions of the semiconductor device. FIG. 3 shows the aluminum content in an example device according to one embodiment of the invention. The aluminum content is shown for active region 122, high aluminum confining regions 142 and 144, and transition region 146.

Beginning with spacer 150, the aluminum content in a spacer layer 150 increases at ramp 152 to a maximum aluminum content 154 within high aluminum region 144. In transition region 146, the aluminum content ramps between the maximum aluminum content 154 and the aluminum content of quantum well barrier 140. Transition region 146 includes a ramp 156, an intermediate structure 158, a step 160, and a ramp 162. The active region 122 includes several steps that form quantum wells 138. A ramp 164 provides a transition between active region 122 and high aluminum content region 142. Ramp 168 provides a transition between the aluminum content of spacer 148 and a maximum aluminum content 166 in high aluminum region 142. The confinement of carriers and efficient electron injection are provided by particular features of the high aluminum regions 142 and 144 and the transition region 146, as discussed below.

A. Transition Region

Transition region 146 is configured to provide efficient electron injection of electrons in the high aluminum confining region 144 into the active region 122. The transition region 146 includes an intermediate structure with low electron affinity. The low electron affinity and high doping give a high conduction band and allow the n-type dopants in the region to provide modulation doping to the adjacent region.

The transition region 146 includes an intermediate structure. In FIG. 3, the intermediate structure is a plateau 158 in the ramping of the aluminum. However, the intermediate structure is not limited to a plateau. The intermediate structure can be any inflection in the ramping of the composition between the narrow bandgap material and the wide bandgap material. An inflection in the ramping is provided where the rate of ramping of aluminum (from the active region toward the confining region) is increasing, then increases to a lesser degree, and then increases again (the ramping could similarly be described as a decrease in aluminum from the confining region toward the active region). A plateau in aluminum content is provided by flattening the ramping of aluminum to zero or near zero over a particular depth of growth and then once again increasing the rate of ramping. The invention also includes non-planar intermediate structures that are formed by flattening the ramping to something greater than zero for a particular depth of growth. In one embodiment, the non-planar intermediate structures of aluminum can be linear or curved or a combination of these. In one embodiment, the intermediate structure is a flattening in the composition ramping for a depth of at least 5 nm, more preferably at least about 20 nm.

The composition (i.e., the content of aluminum) at which the inflection is formed is selected to provide a low electron affinity structure. Electron affinity is a property of the semiconductor material. In some III-V semiconductor materials with aluminum, electron affinity generally decreases with increasing aluminum until a minimum is reached and then electron affinity increases with increasing aluminum.

FIG. 4 shows electron affinity for an AlGaAs system with varying amounts of aluminum. As can be seen in the graph of FIG. 4, in an AlGaAs system, electron affinity decreases substantially with increasing aluminum until a minimum electron affinity is reached at about 45% aluminum. Increasing the aluminum past about 45% results in higher electron affinity.

The aluminum content of the intermediate structure is selected such that the electron affinity in the intermediate structure is lower than the electron affinity in both the active region and the high aluminum region. An intermediate structure with low affinity improves the electron injection of the device. The particular aluminum content of the intermediate structure will depend on the particular semiconductor material used to make the device, the minimum electron affinity of that semiconductor material, the aluminum content in the quantum well barriers of the active region, and the aluminum content in the high aluminum content region. In one embodiment the aluminum content is in a range from about 35% to about 80% (of Al in AlGa). In an alternative embodiment, the aluminum composition of the intermediate structure is selected to be within a desired percentage of aluminum from the electron affinity minimum. In one embodiment the aluminum composition is within about 20% of the minimum, more preferably within about 15% of the minimum, and most preferably within about 10% of the minimum.

More specifically, for an Al_(x)Ga_(1-x)As the aluminum composition can be in a range of about 0.35<X<0.7, more preferably about 0.4<X<0.65. For an (Al_(x)Ga_(1-x))InP system the electron affinity minimum is at an Al content of 0.7. Preferred ranges for the aluminum content of the intermediate structure in this system can be in a range from 0.5<X<0.75, more preferably about x=0.7.

In some materials, the aluminum composition that gives a minimum electron affinity may not be the most preferred composition due to undesired side effects. For example, in an AlGaAs system, the minimum electron affinity occurs at an aluminum composition that is known to have DX centers that reduce electron conduction. FIG. 5 is a graph showing electron conduction band effective mass vs. aluminum composition for AlGaAs. The DX center phenomenon occurs in compositions close to the jump in the electron effective mass at x=0.45, but decreases significantly at slightly higher or lower aluminum compositions. Consequently, in some embodiments, it can be desirable to select an aluminum composition that maximizes electron conductance while minimizing electron affinity. In an AlGaAs system, an aluminum content of between about 50% and 60% can be used.

Alternatively, the issue with DX centers can be resolved by reducing the poor conduction caused by DX centers using techniques known in the art, such as the addition of light to stimulate carriers out of the DX centers. In yet another embodiment, a III-V semiconductor material that does not have DX centers near the electron affinity minimum can be used. For example, AlGaInP is not known to have DX centers at an aluminum composition near the electron affinity minimum.

The transition region 146 includes ramps and/or steps on either side of the intermediate structure 158 to achieve continuous ramping between the active region 122 and high aluminum region 144. FIG. 3 shows ramp 156, a ramp 162, and a step 160 to achieve this continuous ramping. In one embodiment, step 160 can be advantageous to avoid compositions that are prone to DX centers. However, a step is not required and in one embodiment, ramp 162 can extend between intermediate structure 158 and quantum well barrier 140.

Ramp 162 can serve multiple purposes. In one respect, ramp 162 provides a low carrier and charge region adjacent the quantum wells for the residual field to drop. The rate of change of the bandgap is large in ramp 162 to provide a substantial portion of the hole confinement. In one embodiment, a portion of ramp 162 can be substantially undoped. The undoped portion typically extends from the quantum well to a composition less than 45% aluminum. The undoped portion of ramp 162 can provide a region for the residual voltage to drop.

Another feature of the intermediate structure 158 is the use of doping. In one embodiment the doping is at least about 5e18/cm³, more preferably 2e18/cm³. The doping in the intermediate structure coupled with the low electron affinity allows the intermediate structure to be a good electron source to modulation dope the lower Al regions effectively (e.g., ramp 162 and active region 122). The low electron affinity electron source in the intermediate structure provides low resistance electron conduction through the transition region. By achieving low resistance electron conduction, the electric field that would otherwise be induced by the resistive drops, is reduced, thereby enhancing hole confinement.

B. Wide Bandgap Region

The electronic devices of the present invention include one or more regions of wide bandgap material (e.g., high aluminum content regions such as regions 142 and 144), also referred to as a “confining region.” The high aluminum confining regions 142 and 144 advantageously provide confinement for free carriers in the active region. Device 100 typically includes a high aluminum confining region above and below the active region to confine holes and electrons (i.e., regions 142 and 144). However, the invention includes devices with only one high aluminum content region. Where two high aluminum regions are provided, the aluminum content can be the same or different in the different regions.

The high aluminum confining regions 142 and 144 can extend any thickness. In one embodiment, the thickness of the confining regions is limited to minimize the vertical resistance of the device and facilitate manufacturability. The high aluminum confining regions can be less than 100 nm, more preferably less than 50 nm. In a preferred embodiment, the thickness of confining region is less than about 50 nm, and more preferably about 20 nm. Alternatively, the thickness of the confining layer is in a range from about 2 nm to about 50 nm, more preferably in a range from about 5 nm to about 30 nm, and most preferably between 8 nm and 30 nm.

In a preferred embodiment, the aluminum content in the high aluminum confining regions 142 and 144 is in a range from about 60% to about 100%, more preferably between about 70% and 100%. For oxide confined lasers it can be advantageous to have an aluminum content in the confining regions 142 and 144 that is less than 100% to avoid undesired oxidation. In this embodiment, the aluminum content in the confining regions is preferably in a range from 60% and 90%, more preferably about 85%.

In one embodiment, the confining regions 142 and 144 can be described according to the differential in aluminum content between the confining region and the adjacent spacer layer. In a preferred embodiment, the percentage of aluminum content in the confining layer is greater by at least about 15%, more preferably greater by at least about 20%, and most preferably greater by at least about 25% (e.g., the spacer layer has 40% Al and the confinement barrier has 65% Al).

In one embodiment of the present invention, the high aluminum confining regions 142 and 144 include a doping spike in addition to the aluminum spike. The doping spike is preferably in a range from about 5×10¹⁷ to about 1×10¹⁹ on the n-side of the active region and preferably in a range from about 5×10¹⁷ to about 6×10¹⁸ in the confining region on the p-side of the active region. Most preferably the doping in either confining region is in a range from about 1×10¹⁸ to about 3×10¹⁸. Similar to the aluminum spike, the doping spike in the confining region can be selected relative to the dopant level in the spacer layer. In an exemplary embodiment, the dopant level in the spacer layer is in a range from about 1×10¹⁷ to about 1×10¹⁸. In a preferred embodiment, the dopant in the confinement barriers is between about 1.5 and 8 times greater than in the spacer layers, more preferably between about 1.5 and 4 times greater than in the spacer layer.

The high aluminum confining region can be particularly advantageous for device operation at high temperature and/or high bias currents where minority carrier confinement may be lost. Loss of confinement is undesirable because it decreases the efficiency of the light emitting semiconductor device. With n-doping in the confinement barrier layer, the full bandgap delta of the AlGaAs or similar material may be extended into the valence band providing excellent hole confinement. A confining region thickness of 2 nm to 20 nm, more preferably 8 nm to 10 nm should be sufficient to confine the holes. Thus, the minority carriers injected into the quantum well region may be contained in that region by the presence of the confining region (i.e., a hole barrier confines holes and an electron barrier confines electrons). The loss of free carrier confinement can be dramatically reduced or even eliminated.

C. Spacer Layer

In VCSELs, an Al_(0.65)Ga_(0.35)As can normally be used in the spacer layer to provide a large barrier to free carriers in the valence band which ensures good confinement at high bias levels and high temperature, but has an undesirable indirect bandgap. This gives relatively low electron mobility and high vertical series resistance for a given doping level in the n-spacer.

Optionally, spacer layer 148 and/or spacer layer 150 of device 100 can have an aluminum composition less than 45% (e.g., 0.39 or 0.16), which can benefit the device in several ways. First, the graded region between the Bragg mirror and spacer can be replaced with a step in composition to an alloy with the same electron affinity as the mirror layer. This reduces the barrier to electron flow found in previous designs using the linear grade in aluminum composition and result in a reduction in series resistance. The spacer layer can then be a direct bandgap semiconductor. The scattering of majority carriers from the indirect X conduction band to the direct F conduction band now occurs at the Bragg mirror rather than near the quantum wells.

Second the fact that the spacer is a direct bandgap material gives it a much higher electron mobility. Therefore, a given series resistance can be obtained with a much lower donor doping concentration. This reduces the free carrier absorption close to the quantum wells where the E-field standing wave has the highest amplitude. Decreased free carrier absorption can improve the efficiency of the VCSEL.

D. Example Compositions

FIG. 6 illustrates an example composition of Al_(x)Ga_(1-x)As where the aluminum content is varied to form an active region and confining layers above and below the active region. The device includes high aluminum content regions 254 and 266 in the n- and p-confining layers and an inflection 258 in the aluminum ramping on the n side. Beginning with spacer 250, spacer 250 has as an aluminum composition between 10% and 20% (i.e., x is between 0.1 and 0.2) and is doped n-type at 2e16-5e17/cm³. The lower spacer is followed by a linear ramp 251 to 25% where the doping is ramped from that of the spacer to about 2e18/cm³ n-type with a linear ramp which is about 10 nm thick. This is followed by a step at 252 to about 85% aluminum. The 85% layer 254 is doped about 2e18/cm³ n-type and has a thickness between 12 nm and 25 nm. This is followed by a linear ramp 256 in composition to about 65% which is 5 nm with a doping of 2e18/cm³ n-type. This is followed by a 10 nm region 258 of 65% which is n-doped at 2e18/cm³. This is followed by a substantially undoped linear ramp 262 with a length of 15 nm from 65% to 25%. This is followed by the quantum well active region with quantum wells 238 and barriers 240. The p-side begins with a 3e18/cm³ p-doped ramp 264 which is about 7.5 nm thick to a composition of 85%. The 85% layer 266 is from 2e18/cm³ p-doped and is about 20 nm thick. This is followed by a 20 nm ramp 268 at a doping starting at 2e18/cm³ ramping to about 5e17/cm³ with a final composition which matches the p-spacer 248. The p-spacer has a composition of between 10% and 20% and a doping of 5e17/cm³ p-type.

The present invention also includes semiconductor materials where the bandgap is engineered using a composition that does not contain aluminum. Suitable non-aluminum materials include semiconductor materials where the electron affinity minimum is at a composition other than where the energy band gap maximizes. In these materials, a transition region having an intermediate structure (e.g., an inflection in the ramping of the composition) can be used to improve carrier injection. Examples of suitable non-aluminum systems include GaAsP and SiGe.

Where aluminum is not used, the content of another element (e.g., P or Si) is varied in the composition to obtain the wide bandgap and narrow bandgap materials. In addition, the ramping in the transition region is a ramping of the content of this element (e.g., P or Si) rather than aluminum. The non-aluminum compositions can have an electron affinity minimum or a hole affinity maximum at a particular fraction of the element being varied. In one embodiment, the intermediate structure is placed at or near the electron affinity minimum or the hole affinity maximum for these materials. Preferably the content of the varied element (e.g., P, Si, or Al) in the intermediate structure is within about 20% of the content that gives the electron affinity minimum or the hole affinity maximum, more preferably within at least about 15%, even more preferably within at least about 10%, and most preferably within at least about 5%. For purposes of this invention, the forgoing percentages refer to the fraction of the components that are varied to achieve a wideband and a narrow bandgap in the semiconductor material.

In a GaAs_(1-x)P_(x) system, the composition can be ramped between the narrow bandgap material and the wide bandgap material by adjusting the content (i.e., the fraction x) of P. In the narrow bandgap material (e.g., the active region) the content of P can be between about 0.0 and 0.5; in the wide bandgap material (e.g., the confining region) the content of P can be between about 0.7 and 1.0; and the intermediate structure can have a content of P between about 0.5 and 0.7.

For a Si_(x)Ge_(1-x) system, the composition can be ramped between the narrow bandgap material and the wide bandgap material by adjusting the content (i.e., the fraction x) of Si. In the narrow bandgap material (e.g., the active region) the content of Si can be between about 0.0 and 0.2; in the wide bandgap material (e.g., the confining region) the content of Si can be between about 0.5 and 1.0; and the intermediate structure can have a content of Si between about 0.2 and 0.5.

Although some of the foregoing examples describe a VCSEL, the present invention can be carried out in devices other than VCSELs. Those skilled in the art will recognize that the invention can be implemented in other light emitting diodes where injection of carriers from a wide bandgap material to a narrow bandgap material is needed. The injection structure can also be advantageously used with devices that do not have quantum wells. For example, the injection structure of the invention can be implemented with a heterojunction bipolar transistor, which includes a junction of wide bandgap material and narrow bandgap material.

The present invention also includes an injection structure on the p-side of a semiconductor device. An injection structure on the p-side of the semiconductor device is similar to the injection structures described above except that the dopant in the confining layer (including the doping in the transition region) is a p-type dopant. In addition, instead of positioning the aluminum inflection at or near an electron affinity minimum, the aluminum inflection occurs at a hole affinity maximum. As defined above, the hole affinity is the sum of the electron affinity and the energy bandgap. The hole injection structure can be used alone or in combination with the electron injection structure.

The present invention may be embodied in other specific forms without departing from its spirit or essential characteristics. The described embodiments are to be considered in all respects only as illustrative and not restrictive. The scope of the invention is, therefore, indicated by the appended claims rather than by the foregoing description. All changes which come within the meaning and range of equivalency of the claims are to be embraced within their scope. 

1. A light emitting semiconductor device with efficient electron injection from a wide bandgap semiconductor material into a narrower bandgap semiconductor material, comprising: an active region comprising one or more quantum wells and one or more quantum well barriers; an injection structure adjacent the active region, the injection structure being formed from an semiconductor material comprising AlGaAs, the injection structure comprising: an n-doped confining region having the formula Al_(x)Ga_(1-x)As where x is in a range from about 0.7 to about 1.0; and an n-doped intermediate structure positioned between the confining region and the active region, the intermediate structure having the formula Al_(x)Ga_(1-x)As where x is in a range from about 0.35 to about 0.7.
 2. A light emitting device as in claim 1, wherein the intermediate structure comprises an inflection in a ramping of the aluminum content from the active region to the confining region.
 3. A semiconductor device as in claim 1, wherein the doping in the intermediate structure is greater than 5×10¹⁷/cm³.
 4. A semiconductor device as in claim 1, further comprising a substantially undoped portion position between the intermediate structure and the active region.
 5. A semiconductor device as in claim 1, wherein the thickness of the confining region is in a range from about 5 nm to about 100 nm.
 6. A semiconductor device as in claim 1, wherein the dopant level in the confining region is in a range of about 5×10¹⁷/cm³ to about 1×10¹⁹/cm³.
 7. A semiconductor device as in claim 1, further comprising a spacer layer adjacent the confining region, the spacer layer having the formula Al_(x)Ga_(1-x)As where x is in a range from about 0.4 to about 0.6.
 8. A light emitting semiconductor device with efficient electron injection from a wide bandgap semiconductor material into a narrower bandgap semiconductor material, comprising: an active region comprising one or more quantum wells and one or more quantum well barriers; an injection structure adjacent the active region, the injection structure being formed from an semiconductor material comprising AlInGaP, the injection structure comprising: an n-doped confining region having the formula (Al_(x)Ga_(1-x))InP where x is in a range from about 0.8 to about 1.0; and an n-doped intermediate structure positioned between the confining region and the active region, the intermediate structure having the formula (Al_(x)Ga_(1-x))InP, where x is in a range from about 0.4 to about 0.8.
 9. A semiconductor device as in claim 8, wherein the intermediate structure comprises an inflection in a ramping of the aluminum content from the active region to the confining region.
 10. A semiconductor device as in claim 8, wherein the doping in the intermediate structure is greater than 5×10¹⁷/cm³.
 11. A semiconductor device as in claim 8, further comprising a substantially undoped portion positioned between the intermediate structure and the active region.
 12. A semiconductor device as in claim 8, wherein the (Al_(x)Ga_(1-x))InP is substantially lattice matched to GaAs.
 13. A semiconductor device as in claim 8, wherein the thickness of the confining region is in a range from about 5 nm to about 100 nm.
 14. A semiconductor device as in claim 8, wherein the dopant level in the confining region is in a range of about 5×10¹⁷/cm³ to about 1×10¹⁹/cm³.
 15. A semiconductor device as in claim 8, further comprising a spacer layer adjacent the confining region, the spacer layer having an aluminum content that is less than the confining region. 